Attenuation of amyloid‐β‐induced mitochondrial dysfunction by active components of anthocyanins in HT22 neuronal cells

Abstract Alzheimer's disease (AD) is a common form of neurodegenerative disease in the elderly. Amyloid‐β (Aβ)‐associated neurotoxicity is an important component of the neurodegenerative change in AD. Recent studies have revealed a beneficial effect of anthocyanins in improving learning and memory in AD animal models. Using cultured HT22 mouse hippocampal neuronal cells as an in vitro model, we examined in this study the protective effect of ten pure components of anthocyanins against Aβ 42‐induced cytotoxicity and also investigated the mechanism of their protective effects. We found that treatment of HT22 cells with the pure components of anthocyanins dose‐dependently rescued Aβ 42‐induced cytotoxicity, with slightly different potencies. Using petunidin as a representative compound, we found that it enhanced mitochondrial homeostasis and function in Aβ 42‐treated HT22 cells. Mechanistically, petunidin facilitated β‐catenin nuclear translocation and enhanced the interaction between β‐catenin and TCF7, which subsequently upregulated mitochondrial homeostasis‐related protein Mfn2, thereby promoting restoration of mitochondrial homeostasis and function in Aβ 42‐treated HT22 cells. Together, these results reveal that the pure components of anthocyanins have a strong protective effect in HT22 cells against Aβ 42‐induced cytotoxicity by ameliorating mitochondrial homeostasis and function in a β‐catenin/TCF‐dependent manner.


INTRODUCTION
demonstrated that accumulation of Aβ could form Aβ oligomers and extracellular amyloid plaques, which are composed mostly of aggregated Aβ 42 and Aβ 40 peptides. 7,8 It is generally considered that Aβ 42 plays an important role in the pathogenesis of AD 9,10 because Aβ 42 fibril is a major component of the amyloid plaques and is also more neurotoxic than Aβ 40 . Aβ accumulation can potentially lead to mitochondrial dysfunction, [11][12][13] which has emerged as an important pathogenic change in AD. Mechanistically, Aβ may indirectly cause mitochondrial dysfunction through inducing free radical production and oxidative stress in hippocampal neurons of the AD brain. 14 In addition, a series of findings have suggested that early accumulation of Aβ occurs in the import channels of the synaptic mitochondria, 15 which have become an important pathogenic target of Aβ neurotoxicity. 16,17 In line with this suggestion, Aβ accumulation has been suggested to be associated with dysregulation of mitochondrial homeostasis and disruption of its electron transport chain complex. 18 Experimentally, mitochondrial dysfunction often is reflected by findings showing impairment of the mitochondrial membrane potential (MMP), reduction of ATP production, and decrease of mitochondrial mass. 19 Anthocyanins are natural water-soluble flavonoid-type compounds, and some of the identified bioactive components include cyanidin, malvidin, peonidin, delphinidin, and petunidin. 20 Anthocyanins have many biological activities, 21,22 such as antioxidation, 21 anti-inflammation, anticancer activity and neuroprotection, 23,24 and are generally considered nontoxic. A recent study found that anthocyanins exerted a neuroprotective effect in neurodegenerative diseases by reducing oxidative stress and improving mitochondrial function. 24 In an earlier study, it was observed that bilberry anthocyanins, which contained a mixture of natural compounds, could effectively reduce AD pathogenesis and improve learning and memory functions in an AD mouse model. 25 However, it is not known whether some of the known components of anthocyanins also have a neuroprotective effect.
The present study aimed to investigate the neuroprotective effect of the pure components of anthocyanins and the underlying mechanism of their action. The immortalized HT22 mouse hippocampal neuronal cells in culture were used as an in vitro model and were treated with Aβ 42 to induce cytotoxicity. Ten known pure components of anthocyanins, that is, cyanidin, malvidin, peonidin, delphinidin, and petunidin and their respective glycosides (structures shown in Figure 1) were selected for study. We found that these pure components of anthocyanins exerted protection against Aβ 42 -induced cytotoxicity in HT22 cells, but with varying potencies. Mechanistic analysis using petunidin as a representative compound revealed that it improved cyto-toxicity and promoted mitochondrial homeostasis through targeting the β-catenin/TCF signaling pathway in Aβ 42treated HT22 cells. These observations may form the basis for dietary intervention of Aβ-associated AD pathology and its progression by using bioactive components contained in anthocyanins.

Pure components of anthocyanins alleviate Aβ 42 -induced cytotoxicity
HT22 mouse hippocampal neuronal cells were treated with different concentrations (0.625-10 µM) of Aβ 42 for 24 h. Based on the MTT assay, Aβ 42 induced cytotoxicity in a dose-dependent manner, with IC 50 value of ∼5 μM ( Figure  S1A). Inspection of cellular gross morphology showed that the cells appeared to be less healthy after treatment with 5 or 10 μM Aβ 42 for 24 h, although the cell density was not significantly altered ( Figure S1B). Therefore, 5 μM Aβ 42 was used in subsequent experiments to study the protective effect of selected anthocyanin components in HT22 cells and their mechanism of action.
Petunidin (one representative component of anthocyanins) at concentrations ranging from 2.5 to 40 μg/mL exhibited little cytotoxicity in HT22 cells ( Figure S1C), but it restored the viability of Aβ 42 -treated HT22 cells in a concentration-dependent manner ( Figure S1D). N-Acetyl-L-cysteine (NAC), which is a well-known antioxidant 26 and was used as a positive control in this study for cytoprotection, also exerted a similarly strong protective effect against Aβ 42 -induced cytotoxicity when present at a 40 mM concentration ( Figure S1D). Notably, the cell numbers were not significant altered following treatment with Aβ 42 or petunidin alone or both in combination for 24 h ( Figure S1E). Importantly, petunidin at 5 μg/mL improved Aβ 42 -induced change in the gross morphology of cells ( Figure S1F), whereas no significant change in cell density was observed ( Figure S1G). These results demonstrate that petunidin can ameliorate Aβ 42 -induced cytotoxicity and morphological change in HT22 cells.
We also compared the effect of petunidin-3-glucoside, a glycosylated derivative of petunidin (structure shown in Figure 1) in Aβ 42 -treated HT22 cells. Similar to petunidin, petunidin-3-glucoside also exerted a dose-dependent protection against Aβ 42 -induced cytotoxicity in HT22 cells, but apparently the potency of the glycosylated form was lower than the nonglycosylated form ( Figure 2G and H). Similarly, we also tested the protective effect of other eight pure components of anthocyanins (cyanidin, malvidin, peonidin, delphinidin, and their respective glycosylated compounds) at concentrations from 5 to 20 μg/mL F I G U R E 1 Chemical structures of ten anthocyanins tested in this study. The compounds include cyanidin, malvidin, peonidin, delphinidin, petunidin, and their respective glycosylated forms (i.e., cyaniding-3-glucoside, malvidin-3-glucoside, peonidin-3-glucoside, delphinidin-3-glucoside, petunidin-3-glucoside). For comparison, the structures of two commonly used flavonoids (myricetin and quercetin) are also shown. It is of note that the main difference between anthocyanins, myricetin and quercetin is in their C-ring structures (highlighted by the red circles). While anthocyanins have a positive charge (O + ) in their C-rings, myricetin and quercetin do not have a similar positive charge in their respective C-rings. under the same experimental conditions (Figure 2A-F, I, and J). We found that each of the other four anthocyanin compounds (i.e., cyanidin, malvidin, peonidin, and delphinidin) exerted a similar dose-dependent protection against Aβ 42 -induced cytotoxicity in HT22 cells, although their potencies were slightly different. In comparison, the glycosylated compounds displayed a markedly reduced protective effect. It is apparent that the protective effect of anthocyanins is not dependent on the glycosylation, and in fact, glycosylation significantly reduces their neuroprotective effect in the in vitro cell culture model.
In this study, we also tested, for comparison, the protective effect of myricetin and quercetin (structures shown in Figure 1) against Aβ 42 -induced cytotoxicity in HT22 cells under the same experimental conditions. Myricetin and quercetin share similar overall structures with some of the pure anthocyanin compounds tested in this study, but the formers lack a positive charge in their C-ring structure. Interestingly, myricetin and quercetin did not have an appreciable protective effect against Aβ 42 -induced cytotoxicity in HT22 cells ( Figure 2K andL). This observation indicates that the protective effect of anthocyanins likely F I G U R E 2 Protective effect of the components of anthocyanins (cyanidin, malvidin, peonidin, delphinidin, petunidin, cyaniding-3-glucoside, malvidin-3-glucoside, peonidin-3-glucoside, delphinidin-3-glucoside, petunidin-3-glucoside) against Aβ 42 -induced cytotoxicity in HT22 cells. The concentration of Aβ 42 used in this experiment was 5 μM, and the concentrations of each anthocyanin component were 5, 10, and 20 μg/mL. Quercetin and myricetin (at concentrations of 1, 2, and 4 μM) were also tested for comparison. Bars represent mean ± SD (n = 5). # p < 0.05 vs. Aβ 42 treatment alone (i.e., without anthocyanins or flavonoids). Note that similar results (with slightly different concentration range) for petunidin has also been shown in Figure S1, and they are shown here again for convenience of comparison.
is associated with the unique positive charge of the anthocyanin compounds, which usually favors their preferential localization inside the mitochondria (discussed later). Because petunidin was more potent than the other four anthocyanin compounds tested in this study, we thus chose to use petunidin as a representative anthocyanin compound to further study the protective mechanism against Aβ 42 -induced cytotoxicity in cultured HT22 cells (data described below).

Petunidin attenuates Aβ 42 -induced cellular ROS levels
Accumulation of intracellular Aβ aggregates was observed following exposure to 5 μM Aβ 42 for 24 h ( Figure 3A and B). Petunidin and NAC each significantly reduced Aβ 42 accumulation in Aβ 42 -treated HT22 cells ( Figures 3A and B and S2). Aβ 42 was previously found to induce ROS accumulation, contributing to neuronal oxidative stress. 27 In this study, we determined the ROS levels (staining with DCFH-DA) in HT22 cells treated with Aβ 42 or petunidin alone or in combination for 24 h. We found that treatment with Aβ 42 increased fluorescence signal in a concentrationdependent manner, with approximately a 30% increase over control when the cells were treated with 5 μM Aβ 42 ( Figure 3C and D).
Next, we determined whether Aβ 42 -induced ROS accumulation could be reduced by treatment with petunidin. The result showed that after 24 h treatment, petunidin at 5 μg/mL effectively abrogated Aβ 42 -induced ROS accumulation to similar levels as cells jointly treated with NAC (a ROS scavenger) ( Figure 3E-G). Together, these results indicate that petunidin can protect HT22 cells against Aβ 42 -induced oxidative stress.

Petunidin prevents Aβ 42 -induced mitochondrial dysfunction and morphological alteration
Based on the above findings, we hypothesized that petunidin may ameliorate Aβ 42 -induced cytotoxicity by targeting the mitochondria. Mitochondrial membrane potential and ATP levels were commonly used as indicators of mitochondrial function. 16 Compared with the control group, treatment with Aβ 42 increased the JC-1 monomer green fluorescence intensity ( Figure 4A and E) and reduced the JC-1 aggregation (red fluorescence) to JC-1 monomer (green fluorescence) ratio ( Figure 4B), indicating a reduced mitochondrial membrane potential in Aβ 42 -treated HT22 cells. Furthermore, the cellular ATP levels were decreased following treatment with Aβ 42 ( Figure 4G). Joint treat-ment of the cells with Aβ 42 and petunidin decreased the green fluorescence intensity and restored Aβ 42 -induced reductions in the red fluorescence/green fluorescence ratio ( Figure 4C-F) and ATP levels ( Figure 4H). These results indicate that petunidin likely protects the HT22 cells against Aβ 42 -induced decreases in mitochondrial membrane potential and ATP levels, thereby restoring Aβ 42 -induced mitochondrial dysfunction.
Based on the above observations, next, we sought to assess the changes in mitochondrial morphology. Mitotracker green staining indicated that mitochondrial mass was decreased in Aβ 42 -treated HT22 cells ( Figure 5A and B). Furthermore, transmission electron microscopy analysis also suggested that the mitochondria morphology was altered in Aβ 42 -treated HT22 cells with fewer mitochondrial cristae ( Figure 5E). Notably, Mito-tracker red staining showed that exposure of HT22 cells to Aβ 42 induced mitochondrial fragmentation ( Figure 5E), and joint treatment with petunidin significantly increased mitochondrial mass ( Figure 5C and D), restored normal mitochondrial morphology, and attenuated mitochondrial fragmentation ( Figure 5E) in Aβ 42 -treated HT22 cells.
Next, we also examined the effect of Aβ 42 and petunidin on cell levels of three mitochondrial biogenesis-related proteins, namely, PGC1α, NRF1, and TFAM. We found that Aβ 42 treatment significantly decreased the levels of PGC1α, NRF1, and TFAM in HT22 cells compared to the control ( Figure 5F and G), and joint treatment with petunidin restored the levels of these three proteins in Aβ 42 -treated cells ( Figure 5F and G). These biochemical changes offer partial support for the subcellular morphological observations.

Petunidin activates β-catenin/TCF signaling pathway in Aβ 42 -treated HT22 cells
Previous studies showed that Mfn2, Fis1, and Opa1 genes encode mitochondrial membrane proteins and play a critical role in regulating mitochondrial homeostasis. 28 Western blotting analysis of mitochondrial homeostasisrelated proteins suggested that Aβ 42 treatment significantly decreased Mfn2 protein level but increased Fis1 protein level in HT22 cells compared to the control ( Figure 6A-C). In addition, joint treatment of the cells with petunidin reversed these changes in Aβ 42 -treated HT22 cells; that is, it significantly increased Mfn2 protein level but decreased Fis1 protein level ( Figure 6A-C).
Next, we also investigated the possibility that petunidin might activate the β-catenin/TCF signaling pathway. As shown in Figure 6D-G, Aβ 42 treatment decreased the level of nuclear β-catenin protein, with no significant change which are known inhibitors of β-catenin's transcriptional activity. The MTT assays showed that restoration of cell viability by petunidin in Aβ 42 -treated HT22 cells was abrogated by joint treatment with ICG-001 or LF3 ( Figure 7A and B). Importantly, the reduction in cellular Aβ accumulation caused by 5 μg/mL petunidin in Aβ 42 -treated HT22 cells was abrogated by joint treatment with LF3 ( Figure 7C). However, the reduction of ROS by petunidin was not abrogated by LF3 ( Figure 7D-F). These results indicate that while petunidininduced reduction of Aβ 42 accumulation is mediated by activation of the β-catenin/TCF signaling pathway, the reduction of ROS is not mediated by the same signaling pathway. Furthermore, we found that treatment with LF3 completely abolished the ability of petunidin to restore mitochondrial membrane potential ( Figure 8A and B), cellular ATP content ( Figure 8C), and mitochondrial mass ( Figure 8D and E) in Aβ 42 -treated HT22 cells. The results indicate that petunidin-induced restoration of mitochondrial dysfunction likely is mostly mediated by activation of the β-catenin/TCF signaling pathway.

F I G U R E 3 Effect of petunidin on intracellular Aβ and ROS accumulation in
Western blotting analysis showed that the smallmolecule inhibitor LF3 completely abolished the petunidin-induced increase in Mfn2 protein level in Aβ 42 -treated HT22 cells ( Figure 8F and G) but did not alter the petunidin-induced decrease in Fis1 protein level ( Figure 8F and H). Furthermore, a co-IP experiment was conducted to study the interaction of β-catenin with TCF7. The total protein lysates of HT22 cells were immunoprecipitated with antibodies against active β-catenin. We found that Aβ 42 treatment suppressed the interaction of active β-catenin with TCF7 in HT22 cells ( Figure 8I); however, joint treatment of the cells with Aβ 42 + petunidin enhanced the interaction of TCF7 with active β-catenin, and the presence of LF3 abolished the enhanced interaction between the active β-catenin and TCF7 in the cells ( Figure 8I). Based on these observations, it is suggested that restoration of mitochondrial homeostasis by petunidin may be mediated through activation of the β-catenin/TCF signaling pathway.

DISCUSSION
AD is the most common form of dementia in the elderly. 29 Research that aims to identify new, safe, and protective agents against AD is in urgent need. Previous studies have reported that certain natural products may aid in delaying the progression of AD. 29-32 It was recently reported that bilberry anthocyanins reversed AD-related cognitive dysfunction and reduced the hippocampal Tau neurofibrillary tangle number and Aβ levels in the APP/PSEN1 transgenic mice. 25 In the present study, we found that several pure components of the bilberry anthocyanins effectively attenuated Aβ 42 -induced cytotoxicity in cultured HT22 neuronal cells. Furthermore, the neuroprotective actions of petunidin were mediated through restoration of mitochondrial homeostasis and function via activation of the β-catenin/TCF signaling pathway and upregulation of the mitochondrial homeostasis-related protein Mfn2. Mitochondrial function plays an important role in modulating neuronal survival. 19 Mitochondrial dysfunction, which results in decreased mitochondrial membrane potential and ATP levels, drives the cognitive impairment in AD. 16 Thus, attenuation of Aβ-induced mitochondrial toxicity may represent an effective strategy for prevention or halting of AD perhaps at very early stages through dietary supplement-mediated improvements of mitochondrial function. In this study, petunidin, a representative component of anthocyanins, was found to effectively attenuate Aβ 42 -induced cytotoxicity, reduce Aβ accumulation, restore the mitochondrial morphology, and enhance mitochondrial biogenesis in cultured HT22 neuronal cells (Figures S1, S3, and S5). It is suggested that effective attenuation of Aβ 42 -induced mitochondrial dysfunction, including decreased mitochondrial membrane potential and decreased ATP level in Aβ 42 -treated HT22 cells (Figure 4), would be beneficial for preventing or halting the pathogenesis of AD. 17 Furthermore, impairment of the mitochondrial function could decrease cellular ATP level, which likely would also hamper the degradation of the intracellular Aβ 42 .
Mitochondrial fusion-fission dynamics is critical for maintaining mitochondrial homeostasis and neuronal survival and functions. 33 Mitochondrial dynamics is controlled by several proteins, including Mfn1, Mfn2, and Opa1, which are responsible for mitochondrial fusion, and Drp1 and Fis1, which mediate mitochondrial fission. 34 We found that petunidin significantly increased Mfn2 protein expression and decreased Fis1 protein expression in Aβ 42 -treated HT22 cells ( Figure 6). These observations indicate that petunidin may exert its cytoprotective effect in Aβ 42 -treated HT22 cells through enhancing mitochondrial homeostasis to maintain normal mitochondrial biological functions.
Dysregulation of the Wnt signaling pathway has been suggested to be involved in AD pathology. 35,36 In this study, we found that petunidin significantly stimulated β-catenin nuclear translocation ( Figure 6) and promoted the β-catenin/TCF interaction in Aβ 42 -treated HT22 cells ( Figure 8I). Two small-molecule inhibitors (ICG-001 and LF3) of the β-catenin transcriptional activity effectively abrogated the protective effect of petunidin against Aβ 42induced cytotoxicity in HT22 cells ( Figure 7A-C). Interestingly, LF3 blocked petunidin-induced upregulation of Mfn2 protein, but not downregulation of Fis1 protein ( Figure 8F-H). Furthermore, we found that LF3 completely abolished the restorative effect of petunidin on cellular ATP level, mitochondrial membrane potential and mitochondrial mass in Aβ 42 -treated HT22 cells ( Figure 8A-E). However, petunidin-induced reduction of cellular ROS levels in Aβ 42 -treated HT22 cells was not affected by LF3 ( Figure 7D-F). These results indicate that restoration of mitochondrial homeostasis and function, but not ROS, by petunidin is mediated by activation of the β-catenin/TCF signaling pathway.
Structurally, the only difference between anthocyanins, myricetin, and quercetin is in their C-ring structures (highlighted by the red circles in Figure 1). While anthocyanins have a positive charge (O + ) in their C-ring structures, myricetin and quercetin do not have a similar positive charge. Since earlier studies have demonstrated that many organic compounds with a positive charge, such as triphenylphosphonium (a lipophilic cation), 37 rhodamine, 37 methylene blue, 38 and Mito-TEMPOL, 39 are favored to accumulate inside the mitochondria to exert their biological functions, it is, therefore, suggested that an important reason that the anthocyanin compounds are highly effective in protecting mitochondrial damage likely is due to the positive charge these compounds carry (Figure 1), which likely favors their preferential mitochondrial localization and protective action. By contrast, quercetin and myricetin, which are structurally similar to delphinidin and cyaniding but lack a positive charge in their structures, did not have any protective effect against Aβ 42 -induced cytotoxicity under exactly the same experimental conditions used in this study (Figure 2K andL). Here it is also of note that our results with quercetin appeared to differ from those of a previous study 40 reporting that quercetin exerted a protection in HT22 cells following exposure to Aβ [25][26][27][28][29][30][31][32][33][34][35] . The discrepancy in these results might be related to the different Aβ fragments, different quercetin concentrations, and different treatment times used in the experiments.
Interestingly, the results of this study showed that the five nonglycosylated anthocyanin compounds have slightly different potencies for protection against Aβ 42induced cytotoxicity. The rank order of potency is petunidin ≅ delphinidin ≅ cyanidin > peonidin ≅ malvidin (Figure 2). The difference in potencies of these components might be partly due to the different numbers and position of phenolic groups present. Petunidin, delphinidin, and cyanidin have two hydroxyl groups, but peonidin and malvidin only have one hydroxyl group. This might partly contribute to the observation that petunidin, delphinidin, and cyaniding have a slightly stronger protective effect than peonidin and malvidin. It is evident that the glycosylated anthocyanin compounds have a markedly weaker neuroprotective effect, which might be due to the following reasons: First, the glycosylated compounds have a lower permeability across the plasma membrane into the cells. Second, the metabolic conversion (hydrolysis) of glycosylated anthocyanins to the nonglycosylated active form is needed before the glycosylated compounds can exert their protective effect.
One of the potential limitations of our present study is the lack of in vivo data to demonstrate the effectiveness of pure anthocyanins in protection against Aβ 42 -associated neuronal damage in animal models. The in vivo studies using relevant animal AD models might become more feasible in the future when sufficient amounts of pure anthocyanins become more affordable. Nevertheless, it should be noted that in our recent in vivo study using a transgenic AD animal model to test the effectiveness of a crude mixture of anthocyanins, it was observed that the crude mixture of anthocyanins has a strong protective effect against Aβ 42 -associated neuronal damage in vivo (unpublished data). The in vivo protective effect with the crude mixture of anthocyanins offers partial support for the potential effectiveness of the pure anthocyanins in vivo.
In conclusion, the results of our present study demonstrated that pure anthocyanin compounds can effectively attenuate Aβ 42 -induced cytotoxicity and restore mitochondrial homeostasis and function in cultured neuronal cells. Mechanistically, these compounds can promote the activation of the β-catenin/TCF signaling pathways in Aβ 42treated HT22 cells, which then enhances β-catenin-TCF interaction and results in upregulation of the mitochondrial homeostasis-related protein Mfn2. Compared to other phenolics, the protective effect of anthocyanins likely is associated with the unique positive charge of the anthocyanin compounds. The findings of this study suggest that bioactive components of anthocyanins might have the potential to help halt the early stages of pathogenic progression of AD by ameliorating Aβ 42 -induced hippocampal neuronal mitochondrial dysfunction and neurotoxicity. Future studies are needed to identify the direct cellular target(s) that might mediate the cytoprotective actions of anthocyanins.

Cell culture
HT22, an immortalized mouse hippocampal cell line subcloned from the HT-4 cell line, is widely used as an in vitro model in the study of neurodegeneration. 41 The HT22 mouse hippocampal neuronal cells were purchased from the Cell Bank of Shanghai Institute of Biological Science (Shanghai, China) and cultured in complete DMEM, supplemented with 10% FBS and 1% penicillin-streptomycin medium. Cell culture dishes were kept at the 37 • C atmosphere containing 5% CO 2 . Cells were passaged after reaching 60%-80% confluence. The passage of the cells used in experiments was limited to 10 times, and cells were authenticated by short tandem repeat profiling and routinely tested for mycoplasma contamination.

Cell viability assay
The HT22 cells were seeded in 96-well plates at a density of 1500 cells/well and treated with different chemicals for 24 h. After treatment, the MTT assay was used to measure cell viability. The MTT solution (100 μL, at 0.5 mg/mL) was added to each well and cells were incubated for 3 h at 37 • C, 5% CO 2 . After incubation, medium was removed and dimethylsulfoxide (DMSO, 100 μL) was added to each well to dissolve the MTT formazan. The absorbance was measured using a microplate reader (Biotek, Winooski, VT, USA) at 560 nm. The relative cell viability was compared to the vehicle control group.

Morphological analysis, cell counting, and crystal violet staining
Morphological changes of the cells in different treatment groups were visualized with a Nikon Eclipse Ti-U inverted microscope (Nikon, Tokyo, Japan). The HT22 cells were seeded in 6-well plates at a density of 5 × 10 4 cells/well and treated with different chemicals for 24 h. After treatment, cells were trypsinized, and the cell number was determined using a hematocytometer as previously described. 42 For crystal violet staining, cells were fixed with 1% glutaraldehyde for 15 min and stained with 50 μL of 0.5% (w/v) crystal violet solution (dissolved in 20% methanol and 80% deionized water) for 15 min at room temperature. Finally, the image was visualized and captured with a Nikon Eclipse Ti-U inverted microscope.

Immunofluorescence staining
Immunofluorescence staining was performed to determine the Aβ and β-catenin protein expression and the nuclear translocation of β-catenin in the HT22 cells. Cells were cultured on cover slices for overnight. After that, cells were washed three times with PBS for 3 min each time and

Analysis of reactive oxygen species (ROS)
After treatment, cells were treated with 5 μM DCFH-DA and incubated for 20 min at 37 • C, 5% CO 2 . The DCFH-DA-treated cells were washed for three times with PBS. The fluorescence image was obtained with a Nikon Eclipse Ti-U inverted microscope. The flow cytometry data were collected using the MoFlo XDP cell sorter (Beckman Coulter, Indianapolis, IN, USA) from FL1. A minimum of 10,000 cells was analyzed for each sample and data were processed with FlowJo (FlowJo, LLC, Ashland, OR, USA) software.

Mitochondrial membrane potential analysis
After treatment, cells were stained with 10 μg/mL JC-1 working solution and incubated for 20 min at 37 • C, 5% CO 2 . The JC-1-treated cells were washed for two times with JC-1 dyeing buffer. Confocal imaging analysis was performed with a confocal laser scanning microscope at 490 nm (excitation) and 530 nm (emission) for JC-1 monomers and 525 nm (excitation) and 590 nm (emission) for JC-1 aggregates. JC-1 fluorescence was quantified through flow cytometry analysis, in which red JC-1 aggregate was measured at the FL2 channel and green JC-1 monomer was measured at the FL1 channel. A minimum of 10,000 cells was analyzed for each sample with CytExpert (Beckman Coulter, Brea, USA) software.

ATP assay
ATP concentration was quantified by using ATP Assay Kit (Beyotime, S0026) according to the manufacturer's instructions.

Mito-tracker staining
Cells were cultured on cover slides for overnight. After treatment, cells were stained with 200 nM Mito-tracker red solution or 100 nM Mito-tracker green solution and incubated for 20 min at 37 • C, 5% CO 2 . Images were obtained by confocal laser scanning microscope at 579 nm (excitation) and 599 nm (emission) and were analyzed with Zen software (Carl Zeiss). The flow cytometry data were collected using the MoFlo XDP cell sorter from FL1. A minimum of 10,000 cells was analyzed for each sample with FlowJo software.

Transmission electron microscopy (TEM) analysis
After treatment, cells were carefully dissected and immersion-fixed with 2.5% glutaraldehyde solution for 8 h at 4 • C. The fixation solution was removed and cells were incubated with 1% osmic acid for 2 h at 4 • C. Cells were dehydrated with gradient acetone solutions and soaked, embedded, and polymerized with Epon 812 epoxy resin. Finally, ultrathin section was prepared using an ultrathin slicer (0.5 μM, EM UC7, Leica, Wetzlar, Germany) and stained with 5% uranium dioxide-acetate and 0.25% lead citrate for observation with transmission electron microscope (HT7700, Hitachi, Tokyo, Japan).

Western blot analysis
After treatment, HT22 cells were carefully collected at 3000 rpm for 3 min, washed in PBS for one time, and lysed using RIPA lysis buffer with protease inhibitors for 30 min on ice. The supernatant was collected for 8% or 10% SDS-PAGE analysis, and the proteins were then transferred onto PVDF membranes (Millipore, Lincoln Park, NJ, USA). PVDF membranes were blocked with 5% milk, washed with PBS, and incubated with primary antibodies for overnight at 4 • C. After washing, the membranes were incubated with HRP-conjugated secondary antibodies for 1 h at room temperature. Finally, the membranes were developed using Supersignal™ West Pico PLUS Chemiluminescent Substrate (ThermoFisher, Waltham, MA, USA). The band intensity of Western blot images was quantified with Image J Software.

Co-immunoprecipitation analysis
For co-immunoprecipitation (co-IP), cell lysates were incubated with the antibodies against active β-catenin (1 μg/100 μg total lysate) for 1 h at 4 • C. The lysates were then incubated with the prewashed protein A/G agarose beads (20421, ThermoFisher) for 4 h at 4 • C. After washing, the beads were mixed with 2✗ SDS-loading buffer, boiled for 10 min at 100 • C, and used for Western blot analysis.

Statistical analysis
Results shown are the mean ± SD from at least three measurements or independent experiments. Statistical analysis was performed with GraphPad Prism 9.0 software (Graph-Pad, San Diego, CA, USA). For multiple comparison analysis, one-way ANOVA followed by Tukey's multiple comparison tests was performed.

C O N F L I C T O F I N T E R E S T S TAT E M E N T
There are no conflicts to declare.

D ATA AVA I L A B I L I T Y S TAT E M E N T
The data analyzed in this study are available from the corresponding author upon reasonable request.

E T H I C S S TAT E M E N T
Not applicable.